STAG1 mutations cause a novel cohesinopathy characterised by unspecific syndromic intellectual disability.

BACKGROUND: Cohesinopathies are rare neurodevelopmental disorders arising from a dysfunction in the cohesin pathway, which enables chromosome segregation and regulates gene transcription. So far, eight genes from this pathway have been reported in human disease. STAG1 belongs to the STAG subunit of the core cohesin complex, along with five other subunits. This work aimed to identify the phenotype ascribed to STAG1 mutations. METHODS: Among patients referred for intellectual disability (ID) in genetics departments worldwide, array-comparative genomic hybridisation (CGH), gene panel, whole-exome sequencing or whole-genome sequencing were performed following the local diagnostic standards. RESULTS: A mutation in STAG1 was identified in 17 individuals from 16 families, 9 males and 8 females aged 2-33 years. Four individuals harboured a small microdeletion encompassing STAG1; three individuals from two families had an intragenic STAG1 deletion. Six deletions were identified by array-CGH, one by whole-exome sequencing. Whole-exome sequencing found de novo heterozygous missense or frameshift STAG1 variants in eight patients, a panel of genes involved in ID identified a missense and a frameshift variant in two individuals. The 17 patients shared common facial features, with wide mouth and deep-set eyes. Four individuals had mild microcephaly, seven had epilepsy. CONCLUSIONS: We report an international series of 17 individuals from 16 families presenting with syndromic unspecific ID that could be attributed to a STAG1 deletion or point mutation. This first series reporting the phenotype ascribed to mutation in STAG1 highlights the importance of data sharing in the field of rare disorders.

Clinical and molecular characterization of the 20q11.2 microdeletion syndrome: six new patients.

Interstitial microdeletions of 20q chromosome are rare, only 17 patients have been reported in the literature to date. Among them, only six carried a proximal 20q11.21-q11.23 deletion, with a size ranging from 2.6 to 6.8 Mb. The existence of a 20q11.2 microdeletion syndrome has been proposed, based on five previously reported cases that displayed anomalies of the extremities, intellectual disability, feeding difficulties, craniofacial dysmorphism and variable malformations. To further characterize this syndrome, we report on six new patients with 20q11.2 microdeletions diagnosed by whole-genome array-based comparative genomic hybridization. These patient reports more precisely refined the phenotype and narrowed the minimal critical region involved in this syndrome. Careful clinical assessment confirms the distinctive clinical phenotype. The craniofacial dysmorphism consists of high forehead, frontal bossing, enophthalmos, and midface hypoplasia. We have identified a 1.62 megabase minimal critical region involved in this syndrome encompassing three genes­GDF5, EPB41L1, andSAMHD1­which are strong candidates for different aspects of the phenotype. These results support that 20q11.2 microdeletion syndrome is a new contiguous gene deletion syndrome with a recognizable phenotype.

Derivation of pluripotent epiblast stem cells from mammalian embryos.

Although the first mouse embryonic stem (ES) cell lines were derived 25 years ago using feeder-layer-based blastocyst cultures, subsequent efforts to extend the approach to other mammals, including both laboratory and domestic species, have been relatively unsuccessful. The most notable exceptions were the derivation of non-human primate ES cell lines followed shortly thereafter by their derivation of human ES cells. Despite the apparent common origin and the similar pluripotency of mouse and human embryonic stem cells, recent studies have revealed that they use different signalling pathways to maintain their pluripotent status. Mouse ES cells depend on leukaemia inhibitory factor and bone morphogenetic protein, whereas their human counterparts rely on activin (INHBA)/nodal (NODAL) and fibroblast growth factor (FGF). Here we show that pluripotent stem cells can be derived from the late epiblast layer of post-implantation mouse and rat embryos using chemically defined, activin-containing culture medium that is sufficient for long-term maintenance of human embryonic stem cells. Our results demonstrate that activin/Nodal signalling has an evolutionarily conserved role in the derivation and the maintenance of pluripotency in these novel stem cells. Epiblast stem cells provide a valuable experimental system for determining whether distinctions between mouse and human embryonic stem cells reflect species differences or diverse temporal origins.

A de novo duplication of Xp11.22-p11.4 in a girl with intellectual disability, structural brain anomalies, and preferential inactivation of the normal X chromosome.

Only a small number of individuals with duplications within the proximal short arm of the X chromosome have been reported. The majority of patients have duplications encompassing Xp11-p21, or extend more distally into Xp22. We report on a female patient who presented within the first year of life with plagiocephaly, speech delay, and epilepsy. Brain MRI showed a relatively thin cerebral cortex, abnormal periventricular white matter, and abnormal vessels in the left inferior parietal region. Cytogenetic and microsatellite analysis of the patient and her parents showed that she has a de novo duplication of Xp11.22-Xp11.4 on her paternal X chromosome. FISH analysis using fluorescently labeled BACs followed by array analysis including an X tilepath BAC array showed that a 12.3 Mb interval between 40.4 Mb and 52.7 Mb from the Xp telomere (NCBI build 36) was duplicated and excluded the presence of additional rearrangements along the X chromosome. Interestingly, X-inactivation studies in peripheral blood leukocytes showed that the duplicated (paternal) X chromosome was active in the majority of cells, in contrast to other patients with Xp duplications in whom X inactivation is random or skewed toward the normal X. These findings suggest that overexpression of genes from proximal Xp is likely to have contributed to her clinical phenotype.

Novel deletion variants of 9q13-q21.12 and classical euchromatic variants of 9q12/qh involve deletion, duplication and triplication of large tracts of segmentally duplicated pericentromeric euchromatin.

Large-scale copy number variation that is cytogenetically visible in normal individuals has been described as euchromatic variation but needs to be distinguished from pathogenic euchromatic deletion or duplication. Here, we report eight patients (three families and two individuals) with interstitial deletions of 9q13-q21.12. Fluorescence in situ hybridisation with a large panel of BACs showed that all the deleted clones were from extensive tracts of segmentally duplicated euchromatin, copies of which map to both the long and short arms of chromosome 9. The variety of reasons for which these patients were ascertained, and the phenotypically normal parents, indicates that this is a novel euchromatic variant with no phenotypic effect. Further, four patients with classical euchromatic variants of 9q12/qh or 9p12 were also shown to have duplications or triplications of this segmentally duplicated material common to both 9p and 9q. The cytogenetic boundaries between the segmentally duplicated regions and flanking unique sequences were mapped to 9p13.1 in the short arm (BAC RP11-402N8 at 38.7 Mb) and to 9q21.12 in the long arm (BAC RP11-88I18 at 70.3 Mb). The BACs identified in this study should in future make it possible to differentiate between clinically significant deletions or duplications and euchromatic variants with no established phenotypic consequences.